Effects of caffeine on chromosome aberrations and sister-chromatid exchanges induced by mitomycin C in BrdU-labeled human chromosomes.

The BrdU-Hoechst staining technique has been used in analyzing the effect of caffeine (CAF) on chromosome aberrations and sister-chromatid exchanges (SCEs) induced by mitomycin C (MC). CAF increased the frequency of SCE in MC-treated chromosomes in all specimens. The combination of MC and CAF caused a remarkable increase in all types of chromosome aberrations, but the most startling effect was the appearance of many cells with multiple aberrations (shattered chromosomes). The BrdU-Hoechst technique showed that the shattered chromosomes did not appear in cells that had replicated only once, but did occur in cells which replicated twice in the presence of MC and CAF. The large majority of chromatid breaks observed did not involve areas common to SCE; and the SCE frequency significantly increased in spite of the existence of multiple breaks. This indicates that very few of the breaks are incomplete exchanges and that the mechanism for formation of SCE might be different from that of chromosome breaks. In another experiment, monofunctional-MC (M-MC) had a small effect on SCE rates, though it induced shattered chromosomes with CAF post-treatment. Possible differences in the mechanisms leading to SCE and chromosome breaks are discussed.     

The relevance of caffeine post-treatment to SCE incidence induced in Chinese hamster cells

The influence of caffeine post-treatment on sister-chromatid exchanges (SCE) and chromosomal aberration frequencies on Chinese hamster cells exposed to a variety of chemical and physical agents followed by bromodeoxyuridine (BrdUrd) was determined. After 2 h treatment, N-methyl-N′-nitrosoguanidine (MNNG) and cis-platinum(II)diamine dichloride (cis-Pt(II)) induced a 7- and 6-fold increase in SCE, respectively, while 4-nitroquinoline-1-oxide (4NQO), methyl methanesulfonate (MMS), proflavine, and N-hydroxyfluorenylacetamide (OH-AAF) caused a 2–3-fold increase in SCE compared to controls treated with BrdUrd alone. Ultraviolet light doubled the number of SCE. The lowest increase of SCE was obtained with bleomycin and X-irradiation. Caffeine post-treatment caused a statistically significant increase in the frequency of SCE induced by UV- and X-irradiation as well as by 4NQO and MMS but did not alter the number of SCE induced by MNNG, cis-Pt(II), proflavine, OH-AAF, and bleomycin.

Caffeine post-treatment increased the number of cells with chromosomal aberrations induced by MNNG, cis-Pt(II), UV, 4NQO, MMS, and proflavine. With the exception of proflavine, these agents are dependent on DNA and chromosome replication for the expression of the chromosomal aberrations. Caffeine enhancement of cis-Pt(II) chromosomal aberrations occurred independently of the time interval between treatment and chromosome preparations. Chromosomal damage produced by bleomycin and X-irradiation, agents known to induce chromosomal aberrations independent of “S” phase of the cell cycle, as well as the damage induced with OH-AAF was not influenced by caffeine post-treatment.

The enhancement by caffeine, an inhibitor of the gap-filling process in post-replication repair, of chromosomal aberrations induced by “S” dependent agents, is consistent with the involvement of this type of repair in chromosomal aberration formation. The lack of inhibition of SCE frequency by caffeine indicates that post-replication repair is probably not important in SCE formation.     

Interactions of caffeine and phenobarbital on sister chromatid exchanges in rat liver epithelial cell lines treated with 2-acetyl-aminofluorene and N-acetoxy-2-acetylaminofluorene

Using "Fluorescence plus Giemsa" technique, sister chromatid exchanges (SCE) were determined on second-division metaphases in rat liver epithelial cell lines treated with 2-acetylaminofluorene (2-AAF), the procarcinogen, and N-acetoxy-2-AAF (N-OAc-2AAF), an ultimate carcinogen analog. The SCE frequency was found decreased after some conditions of 2-AAF treatment and increased with N-OAc-2-AAF. Phenobarbital (PB) decreased also the SCE frequency but cancelled the 2-AAF action when incubated after the procarcinogen. The addition of caffeine (Caf) cancelled the action of 2-AAF but not of phenobarbital. It is suggested that the mechanism of SCE may have several origins.     

Anthramycin-induced sister-chromatid exchange and caffeine potentiation in the chromosomes of Indian muntjac

Cell-cycle kinetics, sister-chromatid exchange (SCE) and chromosome aberrations have been studied from the skin fibroblasts of the Indian muntjac after treatment with 100 micrograms/ml of caffeine and 0.05 microgram/ml of anthramycin. The cultures were incubated for a period which was sufficient for the completion of two consecutive cell cycles and both the drugs appeared to produce a slight inhibitory effect. When anthramycin-treated cells were however post-treated with caffeine, the cells did not proceed beyond one cycle and exhibited a mitotic block. The SCE frequency in the control and the experiments with caffeine and anthramycin was 8.63, 18.32 and 34.88 per cell respectively. The SCEs were randomly distributed amongst all chromosomes unlike a non-random distribution within the X chromosomes. Caffeine and anthramycin produced only 0.5% and 3.1 cells with chromosome aberrations respectively. Potentiation of chromosome aberrations was observed when the anthramycin-treated cells were post-treated with caffeine. Caffeine potentiation presumably results from an inhibition of the cells to cycle and a failure to repair the effect of the mutagen on DNA.     

Caffeine induces sister-chromatid exchanges during the whole S-phase of the cell cycle

The capacity of caffeine to induce sister chromatid exchanges (SCEs) in different cell cycle stages and the proliferation kinetics were studied. Continuous treatment with this xanthine during the whole second cycle significantly increased the baseline SCE frequency. Pulse-treatment experiments showed that the induction of SCEs by caffeine, which was dose-dependent, was restricted to the S-phase of the cell cycle without effect on G1 or G2 cells. Moreover, unlike other SCE-inducing agents, such as DNA-synthesis inhibitors and DNA-damaging agents, caffeine produced similar SCE increases in cells treated at different times throughout the S-phase. In the light of Painter's model for SCE formation and the known effects of caffeine on the DNA replication pattern, the most likely mechanism of SCE induction by caffeine is an increase in the number of DNA-replication sites.     

Developmental and cytogenetic effects of caffeine on mouse blastocysts, alone or in combination with benzo(a)pyrene

Mouse blastocysts were treated with caffeine and/or benzo(a)pyrene (BP), and the effects on development and on induction of sister chromatid exchanges (SCEs) were examined. Caffeine interfered with blastocyst development in a dose-related manner. At 4 mM, the highest concentration tested, caffeine interfered with development of blastocysts to all four endpoints: hatching, trophoblast outgrowth, inner cell mass (ICM) growth, and two-layer (primary endoderm and ectoderm) differentiation of ICMs. At 2 mM, caffeine reduced the incidence of both ICM growth and differentiation but did not affect hatching or formation of trophoblast outgrowths. At 1 mM, caffeine interfered only with ICM differentiation. Cell proliferation was least sensitive to caffeine and was reduced at concentrations of greater than or equal to 2 mM. Induction of SCEs was most sensitive to caffeine exposure; an increase in SCE frequency was observed at 0.1 and 0.5 mM. When caffeine was added to cultures with BP (1 microM, a concentration that was not embryotoxic and did not induce SCEs), both embryotoxic effects and SCE frequency were increased. The enhancing effect on SCE induction was particularly marked; as little as 0.1 mM caffeine was sufficient to cause doubling of induced SCE frequencies when added to cultures with BP.     

NaCl胁迫对大麦细胞分裂及染色体行为的影响

NaCl溶液培养导致大麦幼苗根尖细胞有丝分裂指数下降,细胞姐妹染色单体交换(SCE)频率增高,且诱发包括染色体断片、后期染色体桥、不均等分裂及间期细胞微核等的染色体行为异常。细胞平均SCE频率及异常分裂细胞的比率与NaCl浓度和作用时间呈正相关。结果提示：NaCl浓度高或作用时间较长时对大麦细胞具有遗传学毒性。 Abstract：The effects of NaCl solution on chromosome behavior and sister chromatid exchanges(SCE)of barley were studied.Abnormal chromosome behavior including chromosome fragmentation,micronuclei,anaphase bridges and unequal split was found in root tip cells of Hordeum vulgare seedlings.Mitotic index decreased but SCE frequency increased significantly when barley incubated with NaCl solution.The effects of NaCl solution depended on its concentration and treatment duration.The higher the treated concentration was,the higher the ratio of chromosomal aberration was.The longer the treatment duration was,the higher the degree of the effects was.The results showed that NaCl solution was genotoxic when the concentration was higher and the treated time was longer.     

Characterization of the enhancing effect of caffeine on sister-chromatid exchanges induced by ultraviolet radiation in excision-proficient xeroderma pigmentosum lymphoblastoid cells

Cells of some excision-proficient xeroderma pigmentosum (XP) cell lines are highly sensitive to post-UV caffeine treatment in terms of sister-chromatid exchange (SCE) induction as well as cell lethality. In the present study, we conducted a detailed investigation of the enhancing effect of caffeine on SCE frequency induced by UV in excision-proficient XP cells, and obtained the following results. (1) Continuous post-UV treatment with 1 mM caffeine markedly enhances UV-induced SCEs and such enhanced SCEs occur with similar frequency during either the 1st or the 2nd cell cycle in the presence of caffeine and 5-bromodeoxyuridine (BrdUrd). (2) The high sensitivity of the cells to post-UV caffeine treatment persists for at least 2 days after UV when irradiated cells are held in either the proliferating or the nonproliferating state prior to the addition of BrdUrd. (3) Caffeine exerts its effect on cells in S phase. (4) Neither BrdUrd in the medium nor the incorporated 5-bromodeoxyuridine monophosphate (BrdUMP) in DNA plays an appreciable role in the expression of the enhancing effect of caffeine. The most likely explanation for our findings is as follows. In excision-proficient XP cells, the cause of SCE formation such as UV-induced lesions or resulting perturbations of DNA replication persists until the 2nd round or more of post-UV DNA replication. If caffeine is given as post-UV treatment, such abnormalities may be amplified, resulting in a synergistic increase in SCE frequency.     

Effects of caffeine-pretreatment on SCE and chromosome aberrations induced by monofunctional- and bifunctional-mitomycin C in bloom syndrome lymphocytes

Bloom syndrome (BS) lymphocytes, which are characterized by a high incidence (75.4 per cell) of SCE, were treated with caffeine (CAF) during the first cell cycle and with monofunctional-(M-MC) and bifunctional-(MC)mitomycin C during the second cycle. The effect on the SCE level was synergistic. The CAF-pretreated cells in combination with M-MC and MC post-treatments, had significantly higher (SCE values 152.5 and 167.9 SCE per cell, resp.) than those treated with M-MC or MC alone during the second cycle (101.1 and 116.4 SCE per cell, resp.). M-MC and MC in the presence of BrdU (without CAF) for 2 cell cycles increased SCE to 157.6 and 169.4 per cell (about twice the control level). M-MC + CAF and MC + CAF treatments for 2 cell cycles did not produce a synergistic effect on the SCE frequency in BS cells; the SCE level was not significantly greater than that with M-MC or MC alone. Normal cells treated with MC and CAF for 2 cycles had a maximum SCE frequency of 156 per cell. This suggests that cells with SCE frequencies above this level may not be able to survive, i.e., this is the “saturation” level of SCE. However, CAF alone had almost no effect on SCE in either BS or normal cells and did not produce multiple chromosome aberrations. The lack of CAF effect on BS cells suggests that the lesions in DNA strands of BS cells which lead to SCE are double-strand lesions. In normal cells CAF is known to significantly slow down DNA-chain growth; the reduced rate of DNA-chain growth in BS is an inherent defect of the cells. Therefore, though CAF enhanced SCE and chromosome aberrations (shattered chromosomes) in combination with alkylating agents, CAF alone did not significantly increase the SCE rate in either BS cells or in normal cells. Thus, processes which may induce SCE are not only related to retarded rate of DNA-chain growth, but also to breaks in the template strand permitting double-strand exchanges to occur.     

The effects of busulphan on the chromosomes of normal human lymphocytes

In vitro exposure of human lymphocytes to busulphan (BUS) produced an increase in chromosome aberrations and in sister-chromatid exchange (SCE) frequency. The distribution of chromosome breaks throughout the karyotype was non-random and they occurred mainly in the G-negative bands. Certain bands had a marked susceptibility to BUS and comparisons with the human chromosome-break distributions reported for a number of drugs revealed that some of these bands were equally susceptible to other alkylating agents. Both the number of chromosome gaps and breaks and the SCE frequency increased with BUS concentration, but only the SCE dose--response was a clearly defined linear relationship. Therefore a standard SCE dose--response curve was constructed for future comparison with the results of similar investigations of patients on BUS therapy.     

The effects of busulphan on the chromosomes of normal human lymphocytes

In vitro exposure of human lymphocytes to busulphan (BUS) produced an increase in chromosome aberrations and in sister-chromatid exchange (SCE) frequency. The distribution of chromosome breaks throughout the karyotype was non-random and they occurred mainly in the G-negative bands. Certain bands had a marked susceptibility to BUS and comparisons with the human chromosome-break distributions reported for a number of drugs revealed that some of these bands were equally susceptible to other alkylating agents. Both the number of chromosome gaps and breaks and the SCE frequency increased with BUS concentration, but only the SCE dose-response was a clearly defined linear relationship. Therefore a standard SCE dose-response curve was constructed for future comparison with the results of similar investigations of patients on BUS therapy.     

Enhanced assays detect increased chromosome damage and sister-chromatid exchanges in heroin addicts

To refine previous studies of chromosome damage (CD) and sister-chromatid exchanges (SCE) in heroin addicts, we applied new methods developed in our laboratory to enhance detection of the cytogenetic effects of low-level radiation exposure in hospital workers. For CD analysis, we applied our thymidine-fluorodeoxyuridine-caffeine (TFC) enhancement procedure in which cells at setup receive 1 x 10(-7) M fluorodeoxyuridine to inhibit thymidylate synthetase and 4 X 10(-5) M thymidine to satisfy the induced requirement, and then in G2 receive 2.2 mM caffeine to modulate DNA repair. For SCE enhancement, caffeine treatment was initiated in G1 at 19 h before harvest. Using both standard and enhanced procedures for CD and SCE analysis, blood samples were evaluated from 20 street heroin addicts and 22 controls. Standard 2-day CD and 3-day SCE assays showed small, insignificant genotoxic increases in addicts while the enhanced CD and SCE assays showed highly significant increases. Most CD events were in the form of chromatid and chromosome breaks. There were no rings and only a few dicentrics were observed in the TFC-enhanced cultures. Although quadriradials are rare, 10 were found in addict TFC-cultures and 3 in control TFC-cultures. With the standard CD assay, the mean number of chromosome breaks per 100 cells was 0.727 for controls and 1.056 for addicts (not significant). With the TFC-enhanced assay, the same measure showed 1.483 chromosome breaks for controls and 5.143 for addicts (highly significant, ANOVA: p less than 0.0001). A highly significant difference was also observed for chromatid-type damage with the TFC-enhanced assay (chromatid breaks per 100 cells: 16.793 for controls; 48.191 for addicts). The SCE data also showed significant differences with the enhanced assay. Scoring 25 cells/condition, standard SCE cultures showed 10.892 SCE/cell for controls and 11.732 SCE/cell for addicts (not significant). With CAF enhancement there were 13.08 SCE/cell for controls and 17.05 SCE/cell for addicts (ANOVA: p less than 0.008). These findings indicate that detection of CD and SCE effects can be significantly enhanced by the use of these new procedures. The finding of greatly increased chromatid damage in the addicts with the TFC procedure suggests that at least part of the CD detected occurred in vitro and is not a product of prior in vivo damage. Therefore exposure to this drug and perhaps other environmental agents may not only leave a residue of DNA or chromosome damage but may also induce a sensitivity to further genotoxic damage that is revealed by using the enhanced procedures.     

姐妹染色单体互换在鹌鹑胚胎细胞染色体间及染色体上的分布

SCE在鹌鹑胚胎细胞间的分布为Poisson分布;在染色体间的分布是非随机的,与染色体的相对长度成正相关（P<0.05）,但也不完全按各染色体的相对长度分布。着丝粒区的SCE相对很高,按染色体的相对长度分布。胚胎的不同性别对每个细胞的SCE平均值无显著影响,但对性染色体Z上的SCE是否有影响还不能做出肯定的结论。     

Mutagenic risk in psoriatic patients before and after 8-methoxypsoralen and long-wave ultraviolet radiation

Sister-chromatid exchange (SCE) analysis was carried out in different age groups prior to and after therapy with 8-Methoxypsoralen (8-MOP) followed by exposure of the patient to long-wave UV-A (PUVA) and compared to control. The SCE frequencies were increased significantly in PUVA-treated patients as compared to their pre-treatment SCE levels and to controls. A significant increase in SCEs was found in smoking PUVA-treated patients as compared to non-smoking PUVA-treated patients. This study indicates a detectable chromosome-damaging effect of PUVA therapy on its human users.     

Increased sister chromatid exchange in bone marrow and blood cells from Bloom's syndrome.

Bone-marrow cells from a patient with Bloom's syndrome cultured for 48 h in the presence of BudR exhibited a striking increase in the number of sister chromatid exchanges (SCEs) in comparison to that in the marrow cells of a patient with treated polycythemia vera (PV). Thus, it appears that an increased incidence of SCE in Bloom's syndrome occurs in various differentiated types of cells, not just blood lymphocytes, and constitutes the syndrome's most characteristic cytogenetic feature. In contrast, the incidence of SCE was not increased in marrow cells and lymphocytes of the particular PV patient studied here, whose cells did exhibit increased numbers of chromatid and chromosome gaps and breaks, presumably as result of the patient's earlier treatment. An increased frequency of SCE was demonstrated in Bloom's syndrome lymphocytes using both a technique based on BudR incorporation and one based on labeling with tritated deoxycytidine. This observation constitutes evidence against the increase of SCE being due to an unusual reaction to BudR. By conventional cytogenetic techniques, chromosome instability, including chromatid and chromosome breaks, but no homologous chromatid interchanges were also recognized in Bloom's syndrome bone-marrow cells incubated in vitro (without BudR) for either 1.k or 16 h. This observation points to the existence of chromosome instability in vivo.     

Proliferation-dependent reduction of sister-chromatid exchange frequency induced by mitomycin C in human lymphoblastoid cells and its suppression by inhibitors of DNA replication

A high frequency of sister-chromatid exchange (SCE) induced in cells of a human lymphoblastoid cell line, NL3, by 2-h treatment with 1 microM mitomycin C (MMC) was maintained after holding the treated cells in a nonproliferating state for 48 h before cells were transferred into the BrdUrd-containing medium for SCE assay. The same was observed in cells treated with 4-nitroquinoline 1-oxide (4NQO) or ethyl methanesulfonate (EMS). In contrast, when MMC-treated cells were transferred into a growth medium and allowed to proliferate for various periods of time before SCE assay, MMC-induced SCE frequency decreased with time and reached near control level after 48 h. The reduction in SCE was also observed in 4NQO-treated cells, though to a lesser extent, but not in EMS-treated cells. When hydroxyurea or 1-beta-D-arabinofuranosylcytosine was given as a post-MMC treatment during this recovery process, such a reduction of SCE frequency was suppressed and the extent of the suppression appears to be roughly parallel to their ability to inhibit DNA replication. Cycloheximide and 5-azacytidine also exerted a similar inhibitory effect on the reduction of SCE. Benzamide and caffeine had no appreciable effect. Our results indicate that the SCE-forming lesions induced by MMC can be eliminated only in proliferating cells, probably during DNA replication.     

Sister-chromatid exchanges in a special form of xeroderma pigmentosum (form II)

The frequency of sister-chromatid exchanges (SCE) was studied in peripheral blood lymphocytes from a xeroderma pigmentosum (form II, XPII) patient. The cells were irradiated with UV or X-rays. In some experiments novobiocin (NB), inhibitor of topoisomerase II, or caffeine (CA), inhibitor of DNA repair were added to the cultures. The level of spontaneous SCE in the patient's lymphocytes was found to be significantly increased in comparison to that in the cells from normal donors. The inhibitors and UV-light caused a rise in the frequency of SCE in the cells taken from normal donors and except for NB, in the lymphocytes from the patient XPII. X-Rays did not increase SCE frequency in normal lymphocytes and lowered it in the patient's cells. SCE frequency rose when inhibitors of DNA replication and repair were used in combination with mutagens.     

Increased frequency of sister-chromatid exchange and chromatid breaks in lymphocytes after treatment of human volunteers with therapeutic doses of paracetamol

Paracetamol was given to 10 healthy human volunteers in 3 doses of 1 g each during a period of 8 h. Blood samples for lymphocyte cultures were taken before and 24 h after paracetamol administration. A small but significant increase was found in the frequency of sister-chromatid exchanges (SCE) after intake of paracetamol (0.187 +/- 0.030 per chromosome before and 0.208 +/- 0.024 per chromosome after). After exposure the mean frequency of chromatid breaks per 100 cells was significantly increased (2.16 +/- 1.33 versus 0.33 +/- 0.50 before exposure). Exposure of human lymphocytes in vitro showed that concentrations of paracetamol above 0.1 mM induced inhibition of replicative DNA synthesis. Increased SCE was found in lymphocytes exposed to 1-10 mM paracetamol for 2 h. Furthermore, 0.75-1.5 mM paracetamol exposure for 24 h increased the frequency of chromatid and chromosome breaks in the lymphocytes. The paracetamol-induced SCE and chromosome aberrations may be secondary effects of paracetamol-induced inhibition of DNA synthesis or due to covalent binding of paracetamol metabolite(s) to DNA.     

Effects of caffeine on sister-chromatid exchanges (SCE) in vivo.

Chinese hamsters were twice treated with caffeine via stomach tube. The single doses were either 20, 100, 200 or 400 mg per kg body weight. A dose-dependent increase was observed in the frequencies of SCE induced in vivo in bone-marrow cells. Two intraperitoneal injections of the chemical mutagens, cyclophosphamide or benzo[a]pyrene, led to a pronounced increase of the frequency of SCE. Simultaneous applications of the chemical mutagens and caffeine decreased the rate of SCE. The effect of caffeine per se to induce SCE, and the mechanisms by which caffeine reduces the level of SCE induced by chemical mutagens are discussed.     

Sequential monitoring of cytogenetic damage in rat lymphocytes following in vivo exposure to aflatoxin B1 and N-nitrosophenacetin

Rats were treated intraperitoneally with different concentrations of aflatoxin B1 (AFB1) or N-nitrosophenacetin (NP). Blood was sequentially drawn by venous puncture at 6, 24, 72, 120 h and 14 days after a single injection of AFB1 or NP. After AFB1 the frequency of SCEs and chromosome aberrations increased progressively and reached a maximum level after 24 h and then decreased with time. By 2 weeks post treatment, the SCE and chromosome aberration values were within the control range. A small but significant SCE induction was observed when rats were treated with NP, but no chromosome breakage was induced even at the highest dose (20 mg/kg). We suggest that the elimination of DNA damage by repair mechanisms and lymphocyte turnover is responsible for the reduction of SCEs and chromosome aberrations with time. This assay seems promising for sequential monitoring of cytogenetic damage in rat lymphocytes following in vivo exposure to genotoxicants.